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Chapter 2. The Modern Science of Infant Cognition

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So, I want to introduce you to the modern science of infant cognition. Infant cognition has been something studied for a very long time. And there was a certain view that has had behind it a tremendous philosophical and psychological consensus. And it's summarized in this Onion headline here. And the idea is that babies are stupid, that babies really don't know much about the world. Now, the work that this Onion headline is satirizing is the recent studies, which I'm going to talk about, suggested that on the contrary, babies might be smarter than you think. And to discover the intelligence of babies we have to ourselves be pretty smart in developing different techniques.

To study what a baby knows, you can't ask your questions. Babies can't talk. You could look at what it does but babies are not very coordinated or skilled so you need to use clever methods. One clever method is to look at their brain waves [laughter]. This child on the right died during testing. It was a tragic — It was crushed by the weights [laughter] of the electrodes. He's happy though. You could study their brain waves. One of the few things babies can do is they could suck on a pacifier. And you might think, well, how could you learn anything from that? Well, for instance, you could build machines that when babies suck on a pacifier they hear music or they hear language, and then you could look at how much they suck on the pacifier to determine what they like.

But undeniably we know most of our — we got most of our knowledge about babies from studies of their looking times. That's one thing babies can do. They can look. And I have up here — This is a picture of Elizabeth Spelke, who is a developmental psychologist who's developed the most research on looking at babies' looking times and what you could learn from them. And I have here two ways you could learn from looking. One is preference. So for instance, suppose you want to know, for whatever reason, do babies like the looks of dogs or cats? Well, you could put a baby down, have a picture of a dog here, a picture of a cat here, and see which one the baby looks at. Babies can move their eyes and that could tell you something. Do babies distinguish pretty faces from ugly faces? Well, put a pretty face here, an ugly face here, see if the baby prefers to look at the pretty one. You could also do habituation and surprise. And much of the studies I'm going to talk about here involve habituation and surprise.

Habituation is a fancy word for boredom. What you do is you show a baby something over and over again. Now, remember from behaviorism the baby will learn this isn't very interesting. Then you show the baby something different. If the baby really sees it as different, the baby will look longer, and you could use that as a measure of what babies find different. For instance, suppose you want to know if the baby can tell green from red. Well, you could show the baby a green patch, a green patch, a green patch, a green patch; the baby'll get bored, then a red patch. If they all look the same to the baby, the baby will just continue to tune out, but if the red looks different the baby will perk up. And this is, in fact, one way they study color vision in babies.

Surprise is related to this. You could show babies something that shouldn't happen. If babies are like — If babies also think it shouldn't happen, they might look longer, and essentially what happens is scientists do magic tricks to explore this very thing. And to start with some real examples, a lot of this infant research has gone back to the Piagetian question of object permanence, asking, "Is it really true babies don't know that objects remain even when they're out of sight?" So one very simple study by Spelke and Baillargeon: Have babies shown a block with a bar going back and forth like that. So the bar just goes back and forth. Now, there's something you do that's so obvious you probably don't even know you're doing it. When you see a display like that, what you assume is there's a bar there, and what that means is there's something in the middle that you've never seen before. But of course, if you were a simple perceptual creature, you would just see that there'd be a bar on top and a bar on the bottom. You wouldn't expect anything in the middle because you never saw anything in the middle. So, what you do then is you show babies this and then you show them either B or C and if we do this with adults you expect B, C is almost a joke. And, in fact, babies respond the same way. Babies expect there to be an entire, complete bar and are surprised and look longer at the broken bar.

Other studies, some of them — Well, here's another study by Rene Baillargeon looking at the same thing in a different way. You show the baby, say a six-month-old, a stage with a block on it. Then a screen rises and obscures the block. Now, if the babies expect the block to still be there, they should think the block should stop the screen. On the other hand, if out of sight out of mind, they should expect the screen to keep going. So, what you do is you set up a couple of displays, one where the block is stopped, the other one where you take this away with a trap door and it keeps going. And, as you see, the baby screams when this happens. That doesn't really happen, but they do look longer.

One final example of an object permanence study. Some of this work's been done at Yale in Karen Wynn's lab, where they look at babies' understanding of addition and subtraction. And a lot of it is done with real objects, but there's also animated versions so here is an animated example [tape playing]. Babies are surprised. They expect 2 - 1 = 1 and when 2 - 1 = 2 or 3 or 0, they look longer, indicating surprise. And even six-month-olds are sensitive to these rudimentary facts of arithmetic, telling us something about their mathematical knowledge, but also telling us something about that they expect things to remain when they're out of sight.

Now, this research suggests that infants' understanding of the physical world is there from the very start, but at the same time not entirely. We know there are certain things babies don't know. Here's an example. Suppose you show babies this. You have a block here and then you have something above there floating in mid air. Babies find this surprising. Even six-month-olds find this surprising. It violates gravity, but six-month-olds aren't smart enough to know that a block just stuck over here is also surprising. Twelve-month-olds will think that it should fall. Six-month-olds don't, and even 12-month-olds don't find anything weird about this, while adults are sophisticated enough to understand that that's an unstable configuration and should fall over. So, although some things are built in, some things develop.

And this raises the question of, "How do we explain development?" How do we explain when babies come to know things that they didn't originally know? Well, one answer is neural maturation, growth of the brain. Most of the neurons you have now in your head, right now, you had when you were in your mother's uterus. What happens in development isn't for the most part the growth of new neurons. It's for the most part pruning, getting rid of neurons. So, the neural structures change radically as babies kind of get rid of excess neurons through development. At the same time though, connections between neurons grow like crazy and they — and this process of synaptic growth where there are the connections across different synapses peaks at about two years. Finally, remember myelination, where you sort of get this fatty sheath over your neuron to make it more effective? That also happens through development, and in fact, it goes through development and even teenagers are not fully myelinated. In particular, they're not fully myelinated in their frontal lobes. Recall that frontal lobes are involved in things like restraint and willpower. And so, it could be the problem is the baby's brain doesn't develop yet.

Another possibility is there's problems with inhibition. This is related, again, to the frontal lobes and this comes out with the A, not B error. So, remember the baby reaches, reaches, reaches. It's moved, reach, follow, keeps reaching the same place. And it could be that babies don't know anything about objects. But another possibility is once you do something it's kind of hard to stop. It takes a bit of control to stop. And there's all sorts of independent evidence that babies lack this control. The part of their brain that could control certain behaviors is just not active yet.

There's a very nice illustration of inhibitory problems from a "Simpsons" episode that actually sort of covers anything you might want to know about developmental differences. So it goes like this [tape playing]. And that basically may sum up much of developmental psychology. That the child essentially — he does A, A, A. It's moved. You go, "doh!" and he keeps going for it. And there's some evidence that's true. Adele Diamond who studies this finds that although kids reach for A, they look for B, as if they know it's there but they can't stop themselves from reaching. And we'll continue this theme a little bit later.

Finally, it might be kids don't know things. Some things you've got to learn. And this is true in all sorts of domains – in the social world, in the economic world, in the political world – and it's true as well in the physical world. In fact, there's some things even adults don't know. So, here's a study by Michael McCloskey with college students. Here's the idea. You have a tube, a transparent — a tube — a hollow tube, and at the top of the tube you throw a ball through so it whips through the tube and it comes out. The question is, "What happens to it?" Does it go in the path of A, or does it go in the path of B? Without looking around, who votes for A? Who votes for B? Here's the weird thing. Whenever I do this at Yale everybody gets the damn thing right [laughter]. At Johns Hopkins, 50/50, [laughter] for A and B. I got to get a better demo. But anyway, college students not here, show systematic biases of incorrect physical intuitions. Here's a twist, and if you found people who were less wonderful than you all, and asked them you'd get a lot of people saying the curving thing. But here's a twist. Ask somebody, "What if you took a tube and you squirted water through it? Where would the water go?" Nobody chooses B. Everybody knows the water would continue in a straight line, suggesting that when you have experience that helps you out, but in absence of experience you're kind of lost.


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